assessment viability of a concentrating photovoltaic
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Assessment viability of a ConcentratingPhotovoltaic/Thermal-energy cogeneration system
(CPV/T) with storage for a textile industry applicationWafa Ben Youssef, Taher Maatallah, Christophe Ménézo, Sassi Ben Nasrallah
To cite this version:Wafa Ben Youssef, Taher Maatallah, Christophe Ménézo, Sassi Ben Nasrallah. Assessment viability ofa Concentrating Photovoltaic/Thermal-energy cogeneration system (CPV/T) with storage for a textileindustry application. Solar Energy, Elsevier, 2018, 159, pp.841-851. �10.1016/j.solener.2017.11.058�.�hal-01820030�
Assessment viability of a Concentrating Photovoltaic/Thermal-energy
cogeneration system (CPV/T) with storage for a textile industry application
Wafa BEN YOUSSEF a,b,* , Taher MAATALLAH a , Christophe MENEZO b , Sassi BEN
NASRALLAH a
a Energy and Thermal Systems Laboratory, National Engineering School of Monastir, University of
Monastir, Avenue Ibn El Jazzar 5019, Tunisia
b University Savoie Mont-Blanc, LOCIE UMR CNRS 5271, campus scientifique Savoie Technolac,
Avenue du Lac Léman, F-73376, Le Bourget-du-Lac, France
ABSTRACT
In this paper, a simulation model of a Concentrating Photovoltaic Thermal-energy cogeneration
system (CPV/T) is investigated in order to evaluate its thermal and electrical performances for
hot water loads referring to a textile industry application. Simultaneous production of electrical
and high-grade thermal energy is provided with a CPV/T system at high temperature. The
electrical and thermal performances of the system operating in Monastir city, Tunisia, are
numerically investigated. Using our developed simulation, the heat and electrical power of the
system have been analyzed for four typical days of the year. Furthermore, the effect of water
flow rate, the outlet fluid temperature and the loss coefficient of the collector have been
involved to identify their impact on the output power.
The simulation process led to evaluate the energy feasibility of the CPV/T system and a
comprehensive economic analysis study of the system under investigation was performed
proving its viability in comparison with the conventional one.
Keywords:
Solar energy cogeneration, CPV/T, industry application __________________________________________
* Corresponding author. Tel: +216 24046012. E-mail address: [email protected]
(W. BEN YOUSSEF).
1. Introduction
Tunisia is located in the most insolated regions of the globe for which the annual average
global solar radiation exceeds the value of 2000 kWh/m² (El Ouderni et al, 2013); making it
one of the promising candidates for meeting its energy needs based on solar energy in the near
future. In fact, the share of renewable energies in the production of Tunisian electrical power
would achieve 30% in 2030. Developments made over the last decade are very promising as
the cost-price of renewable electrical power is continuously decreasing.
Energy from the sun can be directly converted into electrical and thermal energy by the
use of (CPV/T) technology. It is a key barrier to achieve economic viability and widespread
adoption of PV losses related to high operating temperature. In fact, conventional PV systems
were suffering during many decades from low electrical conversion efficiencies. This is due to
the important optic and thermal losses. Hence, the use of such concentrating PV system will
enhance greatly the effective solar density of PV cells. This issue cannot be fulfilled without
using a cooling cell system which insures a moderate PV cells voltage.
Various performances of PVT collector types had been studied. Concentrator type can be
used for elevating the coolant temperature from medium to high level. In this condition, the
numbers of commercially available collectors and systems are still very limited, because of the
major obstacles like costs and product reliability. The numerical analyses become more
comprehensive with the use of powerful analytical tools (T. T. Chow, 2010). X. Xu et al (2013)
studied the heat transfer characteristics and fluid mass flow in a hybrid concentrating
photovoltaic/thermal system (HCPV/T) with a tree-shaped channel. Results show that the
straight channel heat sinks are more commonly used in the cooling because it guarantees a
uniform temperature distribution between PV cells. Whitfield et al (2000) investigated several
designs of small concentrator systems, which can be significantly cheaper than conventional
ones. The prototypes have proved to be robust, reliable, and capable of operating for long
periods. Cappelletti et Al (2015) studied an experimental and numerical approach to determine
the capability of a concentrating PV/T system to heat water. Results presented a 64% thermal
efficiency and concluded that the presence of one-way double channels could be preferred for
higher temperature because it increases the difference of temperature in the receiver and could
avoid damage to the operability of photovoltaic cells. Zondag H.A et al (2002) have developed
numerical models for the simulation of thermal efficiency of a combined PV-thermal collector.
It is found that all models are easily adapted to other configurations and provide more detailed
information, as required for a further optimization of the collector. Reatty et al (2015) proposed
an analytical method to allow the determination of the energy produced from a linear solar
collector. Their method does not depend on the shape of the collectors and, therefore, it is
suitable for diverse systems.
In the last years, a new important aspect of solar cell was discovered. A semi-conductor
junction stack that absorbs solar energy on a wider light spectrum than conventional PV cells
is used in concentrating solar system. CPV/T systems are based on cells with a high conversion
efficiency, in particular those based on III–V materials which can tolerate higher temperatures.
The stack of photoelectric material (Ga, As, In, B, P) constitutes a high performance PV cell.
Nowadays, the use of triple junction cells is more adopted. They have an efficiency
characteristic which can be increased logarithmically with the concentration level and they are
less influenced by the cell temperature increase (Buonomano,2013;Del
Col,2012;Basco,2012;Zondag,2008;skoplaki,2009) . Such cells are commercially available
today; and the efficiencies of advanced cells under development have recently reached very
high values. Researchers are performing a special effort seeking to realize a CPV/T collector
providing elevated-temperature heat at high electrical efficiency. A possible alternative for
increasing fluid CPV/T outlet temperature without decreasing PV electrical efficiency may
consist in the use of an active coolant which absorbs the heat released from the cells. The
amount of absorbed energy by the coolant fluid is very interesting on one hand to cool PV cell
temperature and by the way to maintain a nominal operating voltage at its terminal buses
junctions. In the other hand, this heat energy can be used in Rankine cycles for electricity
production, cooling systems and so forth.
Unlike solar PV system, CPV/T technology is not well developed around the world.
However, several research studies were established to investigate CPV/T system in laboratory
scale and industrial cases. These works studied almost the thermal and electrical efficiencies of
such technology. Calise et al (2012) studied a parabolic trough photovoltaic/thermal collector
with a triangular linear receiver equipped with triple junction cells InGaP/ In GaAs/Ge (Indium-
Gallium Phosphide/ Indium-Gallium Arsenide/ Germanium) which significantly increase the
electrical efficiency of the system. Systems’ performances were improved by the use of this
type of PV cells because their efficiency is expressively better than the silicon cells, especially
when the operating temperature is high. The research institute of the National University of
Australia has carried out a detailed study on a thermal photovoltaic concentration system (Xu
et al, 2012). Several studies investigated the design of the collector as well as the PV cell
characteristics. They worked on two CPV/T systems with a comparison between two types of
PV cells. They concluded that GaAs cells have the best electrical efficiency thanks to their low
resistance in series; however, crystalline cells are characterized by the better thermal efficiency.
Besides, when the direct solar radiation exceeds a certain value, the production performances
are decreased because of the high series resistance leading to high power losses. However, for
the GaAs cells the performance was always excellent. A parabolic trough photovoltaic thermal
prototype was experimentally investigated by Coventry (2005).The concentration ratio of the
system under investigation was 37, the thermal and electrical efficiencies were rated
respectively 58% and 11%. Due to the complexity of the technology, GIBART and Buffet
(2008) have chosen to study a cylindrical reflective surface. For a fixed cooling flow rate and
two different water inlet temperatures, the results showed that the electrical and thermal
efficiencies are higher than those of a conventional system. Moreover, economically, it is
expected that the system will have a return time of 10.5 to 12.8 years. S.Quaia, 2012; Ming,
2011;Rosell, 2005 at the Center for Sustainable Energy Systems (CSES) at the Australian
National University (ANU) developed a combined solar collector (CHAPS). The first
commercial scale demonstration for this technology was completed by the end of 2004 and it
provided electricity and hot water for the heating of a residential college at the ANU. The solar
cells manufactured by ANU were mono-crystalline silicon cells. They were designed to have a
low resistance in series around 0.043 Ωcm² and it was characterized by a yield around 20% at
25°C (under a concentration ratio of 30). The measured results showed a combined efficiency
of 69%. Linear CPV/T performances were studied by N. SHARAN et al (1987); three types of
absorber shapes: tubular, vertical plate and horizontal plate. Comparative performances have
been presented and discussed. Results showed that the efficiency of the solar concentrator
system with a tubular absorber can be distinctly noticed compared to the other configurations,
as it provided the maximum electrical power, the optimum electrical efficiency and the lowest
cell temperature.
Distinctive applications of CPV/T systems have also been studied by several researchers.
Xu et al (2011) analyzed a novel low-concentrating solar photovoltaic/thermal system
integrating a heat pump system with both electrical and thermal output power. Experimental
results showed that the output electrical efficiency is 17.5% and the system heated the water
from 30°C to 70°C. The generated hot water could be used for domestic hot water supply,
space heating or a solar cooling system. Alili et al (2012) investigated a novel application for a
hybrid photovoltaic/thermal collector. The hybrid collector is used to drive a hybrid air
conditioner. The overall system performance was compared to the performance of a
conventional vapor compression cycle (VCC), which is widely used in the UAE, powered by
photovoltaic panels and a solar absorption cycle driven by evacuated tube collectors. The results
showed that this system is very effective in meeting the humidity and temperature requirements
of buildings in hot and humid climates. The overall coefficient performance of the proposed
system is found to be higher throughout the year than that of the other solar air conditioners.
Chemisana et al (2011) studied the coupling of a linear Fresnel concentrator with a channel
photovoltaic/thermal collector. Experimental results are encouraging because the total
efficiency is over 60% when the concentration ratio is above six suns.
The perspective of using high-temperature in CPV/T systems is very interesting since it
extends the number of possible applications. But, such temperature cannot be reached by
conventional PV cells since their voltage drops to low values around high temperature
(Mittelman et al (2007). While higher operating temperatures increase the potential use of the
cogenerated heat, it decreases the electricity production (calise, 2012; Xu et al, 2012;
Conventry, 2005). In fact, for high-temperature the most suitable PV cells for CPV/T systems
is the triple-junction whose nominal efficiency of 40% at 25°C drops around 20% at 240°C.
Therefore, the adoption of such materials may lead to operating high temperature at reasonable
conversion efficiency (slightly lower than 20%) (Calise and Vanoli, 2012). With this regard,
Mittelman et al (2007) studied a CPV/T, which can operate at temperatures above 100°C .The
thermal energy produced is useful for processes such as refrigeration, desalination and steam
production. Buonomano et al (2013) investigated a collector based on a combination of a
parabolic dish and high efficiency solar photovoltaic cells. The main aim of the study was the
design and the analysis of a concentrating PVT system, which is able to operate at reasonable
electric and thermal efficiency at 180°C. Kribus et al (2007) determined that the concentration
operations have beneficial effects on high-temperature operations and in these conditions;
triple-junction cells can approach a nominal efficiency of 40%. They found that the output of
concentrator systems composed of high-efficiency triple-junction solar cells was higher than a
conventional one with crystalline-silicon PV cells because of the high efficiency and superior
temperature coefficient (Mittelman et al, 2007). Nishioka et al (2006) studied a CPV/T system
with triangular receiver recovered with triple junction cells. Results showed that the
performance of the system still excellent even when the fluid temperature is very high (>100
°C).
In particular, few numbers of researchers (Calise and Vanoli, 2012; Mittelman et al,
2007;Jiang et al,2010) performed some experimental and theoretical surveys dealing with
CPV/T systems. A novel miniature CPV/T based on a dish concentrator and a thermal model
of the system was developed in order to predict its performance. The operation at high
temperature of CPV/T systems was also analyzed for both solar cooling (Mittelman et al, 2007)
and water desalination applications .Otanicar et al (2015) proposed an innovative CPV/T
system that incorporates spectral beam splitter and vacuum tube sensors. Results showed that
the thermal load of the cell can be reduced and the outlet temperature can be up to 250 or 300°C.
Recently, Kribus et al (2006) investigated the performance of CPV/T poly-generation systems
at elevated temperatures using simplified models. The results showed that using the waste heat
of CPV/T systems for cooling could lead to higher overall efficiency than trying to generate
additional electricity. Among, the most important foreseeable applications were single effect
and double effect absorption cooling, water desalination, steam production and other industrial
process. The results of these studies and demonstrations showed that CPV/T systems hold very
high potential for market penetration in the energy sector due to their unique features. Indeed,
CPV/T at high temperature was studied by Buonomano et al (2013); the collector was based on
a combination of a parabolic dish and high efficiency solar photovoltaic cells. The CPV/T
system was designed to be integrated in a solar heating and cooling system and it drives a two-
effect absorption chiller. Also an example consists in the use of the high-temperature heat
provided by the PVT to drive a heat engine (Vorobiev et al, 2006) an Organic Rankine Cycle
(ORC) (Kasmadakis, 2011) or a Solar Heating and Cooling system (SHC) (Calise and Vanoli,
2012).
Most of the studies in the literature are focused on the heat transfer improvement of a
CPV/T system with medium outlet temperature and there are a limited number of papers in
which the outlet temperature is high. However, in the present study, a CPV/T system operating
at high outlet temperature is proposed and its output performances will be evaluated before
being used in a textile industry application “Tissue Dyeing”. Differently from traditional
photovoltaic systems, the CPV/T system, allows recovering thermal energy at high temperature
with high electrical efficiency; hence, a coupling between a CPV/T system and storage devices
allows fulfilling the heat demand. Detailed analysis will be performed using TRNSYS
simulation tool (Klein et al,2006) to identify the significant parameters affecting the overall
performance. Indeed, an optimal design of this system for this application will be proposed.
The proposed model is applied to improve the co-generation system capacity and to retain
competitive prices. Also, the model will be used to size the optimal CPV/T system components,
to evaluate the output temperature and power and to compare it with the conventional system
in order to prove its capacity for energy supply and its economic viability.
2. Design and dynamic model of CPV/T system
In this study, we aim to investigate the effects of several parameters influencing the
performance of a CPV/T system dedicated to satisfy the thermal energy loads related to a textile
industry application (BENETTON industry). This prototype is a CPV/T system which is
presented in Fig. 1. It consists of a parabolic trough concentrator, a receiver, a triple-junction
PV cells (InGaP/InGaAs/Ge) and a sun tracking system. The bottom surface of the evacuated
tube in the parabolic concentrating solar collector is covered by PV cells and it is located at the
focus of a parabola made of some highly reflective material. As such, parabolic concentrating
collectors do not receive a significant amount of diffuse radiation. Their useful output energy
is dictated by beam radiation as all the incident beam radiation on the aperture area is reflected
onto the absorber contained in the evacuated tube. The solar cell arrays are superimposed on
the lighting tube of the receiver, and generate electricity when the sunlight is concentrated on
them. Depending on the temperature of the cooling fluid, the electrical efficiency penalization
can be reduced by cooling the photovoltaic cells; and heat can be recovered. In fact, it must be
considered that concentrating solar radiation devices determine an increase of radiative flux on
PV, increasing its operating temperature and therefore decreasing its electrical efficiency.
Hence, it is compulsory that the PV cells would be cooled by the coolant and especially where
the flow would be fully developed. Here, the solar receiver plays a key role in the performance
of energy generation since it houses the solar cells producing electrical power and it is used to
absorb the heat of PV cells for further uses.
Fig. 1. Schematic representation of the concentrating photovoltaic thermal system (CPV/T).
The CPV/T system tracks the sun to collect the maximum of the direct beam radiation.
The solar energy collected will be converted to electric power and thermal energy via the PV
cells and the heated receiver tube. Concentrating photovoltaic thermal systems can operate at
higher temperatures than conventional system such as flat plate collectors. The cooling system
can be adjusted to provide a wide range of temperatures by regulating the flow rate of the
cooling fluid. Therefore, thermal energy may be provided to a variety of thermal processes.
The thermal performance of the concentrating photovoltaic/thermal system depends essentially
on a modified loss coefficient (o), it is based upon the standard collector loss coefficient (𝑜𝑠)
provided by collector manufacturers, the mass flow rate of fluid flowing through the collector
(𝑔𝑡), its specific heat (𝐶𝑓𝑑) and the concentration ratio of the collector (Gc) :
o = {
𝑜𝑠,𝑜𝑠
𝑔𝑡𝐶𝑓𝑑𝐺𝑐≥ 1
𝑔𝑡𝐶𝑓𝑑 (1 − 𝑒𝑜𝑠
𝑔𝑡𝐶𝑓𝑑𝐺𝑐) ,𝑜𝑠
𝑔𝑡𝐶𝑓𝑑𝐺𝑐< 1
(1)
The concentration ratio (Gc) can be defined as the ratio of the aperture area 𝐴𝑎𝑝 to the receiver
area 𝐴𝑟𝑒𝑐:
Gc =𝐴𝑎𝑝
𝐴𝑟𝑒𝑐 (2)
The CPV/T system produces both electrical and thermal energy, and each type of the produced
power is described by a separate expression. The overall performance of the CPV/T is often
evaluated using the well-known thermal and electrical efficiencies, which are conventionally
related to the incident beam radiation and to the collector aperture area.
The electrical efficiency of the triple-junction cells,𝜂𝑝𝑣, depends on the concentration ratio,𝐺𝑐,
and to the PV cell temperature, 𝑇𝑝𝑣, and it can be computed by the following equation
(Buonomano et al, 2013;Minget al, 2011;Calise and Vanoli, 2012;Kribus et al, 2006):
𝜂𝑝𝑣 = 0.298 + 0.0142ln 𝐺𝑐 + [-0.000715+0.0000697ln 𝐺𝑐] (𝑇𝑝𝑣 − 298) (3)
At any time-step, the fluid outlet temperature, 𝑇𝑜𝑢𝑡, can be calculated using the following
expression (Klein et al 2006):
𝑇𝑜𝑢𝑡 = 𝑇amb + 𝑜𝜏𝛼 × 𝐼𝐴𝑀 × 𝐺 ×𝐺𝑐
𝑜𝑠 (4)
where 𝑇amb, 𝑜𝜏𝛼, 𝐼𝐴𝑀 are respectively the ambient temperature, the thermal collector loss
coefficient and the Incidence Angle Modifier.
𝐺, 𝐺𝑐 𝑜𝑠 are respectively the beam irradiation, the concentrating ratio and the standard collector
loss coefficient.
The PV module temperature 𝑇𝑝𝑣,𝑚𝑜𝑑 can be then calculated with respect to the following
equation (Klein et al 2006):
𝑇𝑝𝑣,𝑚𝑜𝑑 = 𝑇amb +1−
𝜂𝑐τα
𝐺𝜏𝛼
𝑜s
(5)
where 𝜂𝑐 , τα are respectively the electrical efficiency at reference temperature and the module
transmittance-absorption
For a given incident radiation energy on the collector aperture, each type of the produced power
is described by a separate expression. The thermal output power depends essentially on the
output fluid temperature and its characteristics such as the specific heat and the mass flow rate.
The electrical output power depends mainly on the incoming solar radiation, the PV module
efficiency and the outlet temperature. It is reduced by the electricity lost in the module
connections (𝜂𝑚𝑜𝑑), the inverter and the optical losses (𝜂𝑖𝑛𝑣 , 𝜂𝑜𝑝 ).The two forms of the output
power can be expressed by the following equations (Buonomo et al,2013; Kribus et al,2006):
𝑃𝑒𝑙𝑒𝑐 = 𝐺𝑐𝐺𝐴𝑝𝑣𝜂𝑜𝑝𝜂𝑚𝑜𝑑𝜂𝑖𝑛𝑣𝜂𝑝𝑣 (6)
𝑃𝑡ℎ = 𝑚𝑓𝑑̇ 𝐶𝑓𝑑(𝑇𝑜𝑢𝑡 − 𝑇in) (7)
where 𝐶𝑓𝑑 is the specific heat at the average fluid temperature, 𝑚𝑓𝑑̇ is the mass flow, and 𝑇𝑜𝑢𝑡
and 𝑇𝑖𝑛are the outlet and inlet temperatures respectively of the fluid.
The electrical and the thermal efficiency, (𝜂𝑡ℎ, 𝜂𝑒𝑙𝑒𝑐), of the system can be expressed
respectively as the ratio between the electrical output power and the thermal output power to
incident solar radiation on the aperture area of the CPV/T system as follows (Buonomano et al,
2013;Minget al, 2011;Calise and Vanoli, 2012;Kribus et al, 2006, Davide et al,2014):
𝜂𝑒𝑙𝑒𝑐 =𝑃𝑒𝑙𝑒𝑐
𝐴𝑎𝑝𝐺 (8)
𝜂𝑡ℎ =𝑃𝑡ℎ
𝐴𝑎𝑝𝐺 (9)
CPVTs' high efficiency and multi-output nature can be applied for many industrial
applications using high temperature. In this context, a CPV/T prototype will be designed and
optimized to simulate its contribution for the cogeneration system production in order to meet
the calorific and electrical requirements of a textile factory located in Monastir city. In fact, the
energy produced has to meet the needs of the dyeing task of this company. Thus, we intend to
establish the optimal size of the CPV/T installation based on a simulation of its performances
using TRNSYS software. Solar tracking systems, weather data appropriate to the location, a
better arrangement of the PV cells and a suitable sizing to the needs are crucial. Consequently,
the simulation results will be used to evaluate energy and economic performance of the
proposed CPV/T system.
2.1.CPV/T simulation model
A sensitivity analysis of some parameters will be made by TRNSYS simulations. The
installation of the CPV/T system is modeled with this well-known software. If all the
components of the system have been identified with a mathematical explanation of each
component, parameter values of the geometry and the weather conditions used in the simulation
are entered as input parameters and the output results are registered in the output format.
The use of this development model allows the acquisition of some parameters. Its validity
is tested by comparing simulation results to experimental ones and good agreements were being
noted. TRANSYS is a powerful simulation software, comprehensive and extensible, and it is
dedicated to the dynamic simulation of energy systems. We have also noticed that TRNSYS is
effective and support the choice as a reliable simulation tool which can be used to predict the
performances of CPV/T system and to show the utility of all works which will be carried out in
this study.
In order to investigate the dynamic thermal and electrical behavior of CPV/T system, a
parametric study will be performed under different operating conditions. The influence of
several factors such as date, mass flow rate, outlet temperatures of the working fluid and
temperature of PV cells, collector loss coefficient on the instantaneous electrical and thermal
performance will be analyzed. All simulations were introduced in the TRNSYS model, we note
that all tests are presented in local time (GMT+1), we use a time step equal to an hour, and the
geographical conditions of Monastir (Tunisia) region ( 35°46.6794′ N latitude, 10°49.5702′ E
longitude and 20m above sea level).
Various assumptions have been taken into account to facilitate the theoretical analysis; the
thermal exchanges in the absorber are studied according to the following assumptions:
- The dimension of the receiver and the surface of the collector are constant,
- The ambient temperature around the solar collector and the inlet temperature of the
water are uniform,
- The solar flux at the absorber is uniformly distributed,
- Thermo-physical properties of the collector components are constant.
The parameters characterizing the simulated CPV/T system are illustrated in Table 1.
Table 1: CPVT design parameters used in the simulations.
Parameter Value
Collector Length
Width
4m
1m
Rim angle 90°
Concentration ratio 10
Receiver Diameter 0.1m
triple Junction PV cell Thermal conductivity
Emissivity
Inverter efficiency
Module efficiency
50w/m.k
0.98
0.9
0.9
coolant fluid (water) Flow rate
Inlet temperature
10Kg/h
25°C
2. Results and discussions
To study the CPV/T behavior under Monastir climatic conditions, the numerical
simulation has been carried out on four typical days of the year; the equinoxes of spring (21th
March) and autumn (22th September) and days of the solstice summer (21th June) and winter
(21th December ) are considered in the simulation.
The hourly outlet temperature of the coolant during the above-mentioned days is shown
in Fig.2. (a). Also the hourly electrical and thermal power of the CPV/T is illustrated
respectively in Fig.2. (b) and Fig.2. (c).
Fig.2.
Fig.2. Instantaneous variation of the outlet temperature (a), thermal power (b) and produced electricity
(c) of the CPV/T module during the solstices (summer/winter) and the equinoxes (spring/autumn).
It is clear that the trends of variation of these parameters are linearly dependent to the solar
radiation profile. As shown in Fig.2. (a)), the CPV/T outlet coolant temperature begins to
increase from sunrise to midday from which it will decrease until the sunset. The maximum
production of electricity and heat output power are registered at noon and they differ from one
date to another (Fig.2. (b), (c)). The increase of the solar radiation leads to an increase in solar
heat gain, so thermal and electrical efficiency increases. The value of the useful power absorbed
by the receiver tube during the summer is greater than the gain power in the winter. The
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beneficial periods of the installation in winter are also shorter compared with those during the
spring because the sunshine duration is shorter in winter than during other seasons of the year.
We note also that the maximum thermal and electrical powers occurring in the summer solstice
day while the minimum values are observed in the winter solstice day. This can be explained
by the change in elevation of the sun and its apparent path in the sky and by the higher solar
radiation occurred in summer day relatively compared to the lower solar radiation in winter
day.
Fig. 3 illustrates the outlet temperature distribution and the cogenerated powers in terms
of various flow rate values. In fact, when the flow rate is increased, a decrease in the outlet
temperature is observed (Fig.3 (a)). This is can be explained by the fact that the convection heat
transfer coefficient is very sensitive to the coolant flow rate variation; the increase of the mass
flow rate increases the convection heat transfer coefficient and therefore the heat transfer rate.
Indeed, at high flow rate, the flow residence time in the receiver becomes too short and less
heat can be removed resulting in higher receiver channel temperature. So, the water temperature
cannot be raised as much as estimated, leading to a decrease in the thermal output power (Fig.3
(b)) and an increase in the electrical one (Fig.3 (c)). Therefore, in order to optimize the CPV/T
performance, it is thought that an optimal mass flow rate exists allowing the optimum thermal
output power without dropping the electrical efficiency.
Fig. 3. Instantaneous variation of outlet temperature (a), thermal power (b) and produced electricity (c) of
the CPV/T module in terms of mass flow rate values.
As shown in Fig. 4(a), during the day, the increase of the solar radiation leads to an
increase in the outlet temperature. In fact, the higher the radiation is, the higher both radiative
and convective losses are, because of the increase of the receiver temperature. Fig. 4(b) shows
the variation of the thermal and electrical efficiencies in terms of the outlet water temperature.
The thermal efficiency increases as the outlet water temperature increases due to higher thermal
losses to the environment since the none converted energy to electricity is mostly regained as
2 4 6 8 10 12 14 16 18 20 22
0
200
400
600
800
(c)
ele
ctri
cal p
ow
er
(w)
time (h)
q=10 kg/h
q=20 kg/h
q=30kg/h
2 4 6 8 10 12 14 16 18 20 22
20
40
60
80
100
120
(a)
ou
tle
t te
mp
era
ture
(°C
)
time (h)
q=10 kg/h
q=20 kg/h
q=30 kg/h
2 4 6 8 10 12 14 16 18 20 22
0
500
1000
1500
2000
(b)
the
rma
l p
ow
er
(w)
time (h)
q=10 kg/h
q=20 kg/h
q=30 kg/h
heat. This fact leads to decrease the PV cell temperature and therefore, its electrical efficiency
rises.
Fig.4. Instantaneous variation of the outlet temperature, beam radiation (a), electrical and thermal
efficiencies (b) of the CPV/T module (b).
Fig.5 shows the variation of CPV/T performances in terms of different values of the
collector loss coefficient (o). Decreasing the heat loss coefficient leads to an increase in thermal
and electrical outlet energy. From Fig.5, one can observe that with low values of loss
coefficient, the recorded outlet fluid temperatures are higher than those corresponding to high
loss coefficients. In fact, the outlet fluid temperatures reach its maximum values equal to 130°C
and 100°C corresponding respectively to loss coefficient values of 2 and 10. Besides, this
caused a decrease of the maximum heat capacity and electrical power respectively from 580W
to 450W and from 1300W to 1100W (fig. 5(b) and (c)). We can then notice that the produced
power is inversely proportional to the heat loss coefficient. We can also deduce that it is
fundamental to reduce loss damage to achieve optimum performance.
Fig. 5. Instantaneous outlet temperature (a), thermal power (b) and produced electricity (c) of a CPV/T
module in terms of collector loss coefficients.
3. Technical sizing of the proposed CPV/T system for the industry application
A sensitivity analysis of some parameters has been made in order to evaluate electrical
and thermal energy produced by a CPV/T system. Concentrator photovoltaic solar thermal
energy offers enormous potential, but has not yet benefited the industrial sector, this energy can
provide a natural and economical form of energy that a large part that the industry will need.
Moreover, it has the potential of reaching competitive costs compared to conventional power.
Hence, the CPV/T cogeneration plant may offer a significant advantages in economic viability
particularly for medium and large thermal-energy loads. The energy demands (heating and
6 8 10 12 14 16 18 20 22
0
100
200
300
400
500
600(c)
ele
ctri
cal p
ow
er
(w)
time(h)
o=2
o=5
o=10
6 8 10 12 14 16 18 20
20
40
60
80
100
120
(a)
ou
tlet te
mp
era
ture
(°C
)
time (h)
o=2
o=5
o=10
6 8 10 12 14 16 18 20
0
200
400
600
800
1000
1200
1400
(b)
the
rma
l po
we
r(w
)
time (h)
o=2
o=5
o=10
electricity) of the industry are determined relating to many considered conditions. For the
current industrial load, the dyeing task of BENETON industry has been considered.
The company of BENETTON, located at Monastir city, was created in 2003. After the
dismantling of the multi-fiber agreement, the company decided to carry out two new projects
in Tunisia, where several methods are applied on tissue which requires a high demand of
electricity and gas consumption. Dyeing task is a technique for coloring a textile material in
which a dye is uniformly applied to the tissue support. The penetration of the dye into the fiber
requires that the fiber should be accessible. Nevertheless, the fibers are not accessible to the
dye beyond the glass transition temperature, which sometimes is above 200°C. The textile
factory uses a gas boiler to accomplish this task. The daily and monthly demands of this
application and all its technical needs are summarized in table 2.
Table2. Textile industry Loads for dyeing task.
Data (Dyeing task) Value
Water flow rate ( day) 15 m3
Focal Power Max (burner) 4650 kW
Highest temperature 200 °C
Gas consumption ( m3/month) / (m3/day) 105190 / 3504
Electricity consumption ( kWh/month)/ (kWh/day) 125 000 / 4167
In order to satisfy the hot water demands related to the dyeing task, it is necessary to
determine the optimum configuration of the CPV/T system which guarantees the maximum
possible water outlet temperature. The analysis was performed for a system with storage tank
of solar heat. In fact, basing on scenarios when there is a necessity for an auxiliary heat support,
the addition of thermal storage may improve the competitiveness of the combined system by
reducing the hourly need for a backup heat source and therefore the consumption of
conventional energy.
Table3. Technical configuration of the proposed CPV/T system.
Parameter Value
Collector aperture area 10*4m2
Rim angle () 90°
Concentration ratio 20
Optical efficiency 0.9
Receiver Diameter 0.2m
triple Junction PV cell Thermal conductivity
Emissivité
Inverter efficiency
Module efficinecy
50 w/m.k
0.98
0.9
0.9
coolant fluid (water) Flow rate
Inlet temperature
220 Kg/h
25°C
Simulation time Day 21 juin
The proposed CPV/T system, described in table 3, for the industry dyeing task is equipped
with a dual tracking system composed of two axis, a vertical one which ensure to follow the
solar azimuth displacement while the horizontal axis track the angular high of the sun. Fig.6
illustrates the hourly variations of the outlet water temperature, the hourly output thermal and
electrical power on the summer solstice day. One can observe that the outlet hot water
temperature reaches a maximum value of 220°C at midday and attain values about 200 °C
around solar noon, which meet the required temperature of dyeing. Moreover, the diurnal
cumulated electrical energy is about 56 kWh with an average power of 3 kW while the thermal
energy capacity of the CPV/T prototype produces 198 kWh with an average power rating 11
kW. (Fig.6)
Fig. 6. Hourly variations of the outlet water temperature, the hourly output thermal and electrical
power on the summer solstice day of the proposed CPV/T system
To insure a high-energy efficiency of the whole system, a storage tank has been
combined. In addition, to limit heat losses on the distribution line it is recommended to set up
a control system, so that the boiler has to supply only the heating of the fluid into the storage
tank. Fig.7 shows the variation of the hourly heat losses of the storage tank to the environment.
It is clear that these losses increase linearly during the night because of the strong temperature
gradient whereas as soon as the sun rises, it oscillates around the value of 110 KJ/h.
2 4 6 8 10 12 14 16 18 20 22 24
0
50
100
150
200
250
thermal power
electrical power
outlet temperature
time (h)
ou
tle
t te
mp
era
ture
(°c
)
0
5000
10000
15000
20000
25000
ou
tpu
t p
ow
er
(w)
Fig.7. Instantaneous profile of the thermal energy losses from the storage tank to the environment.
These results are very encouraging since the proposed solution proved its capacity to satisfy the
thermal load of the dyeing need of the plant with high thermal and electrical efficiency and it
presents 20% of the industrial consumption. In fact, the maximum value of the thermal and
electrical efficiencies were rated respectively 62% and 21% (Fig.8).
Fig. 8. Daily evolution of the electrical and thermal efficiency of the CPV/T.
We have developed an innovative process that deserves to be executed and developed,
the energy efficiencies obtained are promising, and it is desirable that they are to be taken into
account for a service not yet available in this company.
Hence, in order to satisfy the energy demands of BENETTON industry, it will be necessary to
use three parallel CPV/T systems. Those systems dimensioned for the heat demand, uses three
modules covering (40*3 m2), and an outlet flow of hot water equal to 660 Kg/h and a storage
tank of volume 0.66 m 3 (Fig.9).
Fig.9. CPV/T system linked to the involved textile application.
4. Economic analysis of the proposed CPV/T system
The simulation model allowed us to evaluate the instantaneous thermal and electrical
performance of the proposed CPV/T system plant by identifying its optimal characteristics for
each component. The results show that a considerable amount of thermal and electrical energy
can be produced by the proposed CPV/T. In fact, the monthly electrical and thermal production
of the plant is respectively 4680 kWh and 17820 kWh.
The required natural gas and electricity for the dyeing task can be replaced by this solution,
which has to prove its long-term economic viability. For this reason, an economic analysis has
to be realized comparing the CPV/T system and the traditional system costs (gas boiler)
operating under the same conditions.
The maintenance and operating costs of this installation(𝐶𝑚𝑎𝑖𝑛𝑡𝑒𝑛𝑎𝑛𝑐𝑒 , 𝐶𝑜𝑝𝑒𝑟𝑎𝑡𝑖𝑛𝑔) are associated
with the modules cleaning, the control system, the imperfect component replacement, and the
insurance in case of malfunctions due to weather conditions or user mismanagement. These
costs depend on the system dimension and, together with the CPV/T system cost 𝐶𝐶𝑃𝑉/𝑇
constitute the project cost 𝐶𝑝𝑟𝑜𝑗𝑒𝑐𝑡 (sheriff et al, 2006; Carlo and Fabio, 2013):
𝐶𝑝𝑟𝑜𝑗𝑒𝑐𝑡 = 𝐶𝐶𝑃𝑉/𝑇 + 𝐶𝑚𝑎𝑖𝑛𝑡𝑒𝑛𝑎𝑛𝑐𝑒 + 𝐶𝑜𝑝𝑒𝑟𝑎𝑡𝑖𝑛𝑔 (10)
Also, the investment cost of the CPV/T system,, is estimated by considering the current costs
of the various parts of the system (PV cells, inverter, pump, tank, tracking system, cables, etc.)
The cost of the CPV/T system takes into account also the different necessary devices can be
given by the following formula (sheriff et al, 2006; Carlo and Fabio, 2013):
CCPV/T = 𝐶𝑃𝑉𝑐𝑒𝑙𝑙𝑠 + 𝐶𝑜𝑝𝑡𝑖𝑐 + 𝐶𝑡𝑟𝑎𝑐𝑘𝑖𝑛𝑔 𝑠𝑦𝑠𝑡𝑒𝑚 + 𝐶𝑎𝑑𝑑𝑖𝑡𝑖𝑜𝑛𝑛𝑒𝑙 𝑐𝑜𝑚𝑝𝑜𝑛𝑒𝑛𝑡𝑠 +
𝐶𝑐𝑜𝑜𝑙𝑖𝑛𝑔 𝑠𝑦𝑠𝑡𝑒𝑚 + 𝐶𝑖𝑛𝑣𝑒𝑟𝑡𝑒𝑟+𝐶𝑇𝑎𝑛𝑘+𝐶𝑑𝑒𝑠𝑖𝑔𝑛 (11)
Considering a system life span equal to 20 years, the yearly variation of the costs of the various
sub-systems and the whole system are estimated and the yearly trend variations of the generated
cash flows are described in Table 4.
Table 4: Economic analysis results.
CPV/T module cost CPV/T system cost Economic analysis results
Component Cost(€) PV cells
Optic
Additional component
Tracking system
2800 2546 2076 970
Total 8392
component Cost(€)
Modules( 3) Cooling system Inverter Design and tank
25176 1215 2025 5817
total 34233
year Cash-flow (€)
year Cash-flow (€)
year Cash-flow (€)
0
1
2
3
4
5
6
-34233
-28008
-22349
-17205
-12528
-8276
-4411
7
8
9
10
11
12
13
-897
2297
5200
7840
10239
12420
14403
14
15
16
17
18
19
20
13206
17845
19335
0689
21920
23039
24056
From table results, we can calculate the profitability of the CPVT project to assess its potential
by calculating the net present value (NPV) and the internal rate of return (IRR). The NPV can
be computed using the following expression (sheriff et al, 2006; Carlo and Fabio, 2013):
NPV=∑ 𝑐𝑓(1 + 𝑘)−𝑡𝑇𝑡=0 (12)
Where 𝑐𝑓 is the expected cash flow per period, k is the required rate of return, and T is the
number of periods over which the project is expected to generate incomes (system life).
Thus, a discount pay-back (DBP) of about 8 years, a NPV of about 33 k€ and an IRR equal to
19%, compared to a discount rate of 10%, have been achieved representing satisfactory
outcomes.
Indeed, in order to have a clearer view of the economic performance of the system taking
into account the continuous increase of the gas and electricity costs during the next few years.
A considerable average gain is earned basing on an annual economic study. In fact, the CPV/T
reaches the required temperature for about 5 hours per day (around the midday), and during the
period surrounding solar-noon an auxiliary boiler is necessary to be switched-on operating
heating the water for the dyeing task. As it is shown in Fig.10 the hourly load for heating water
of the dyeing task in the studied textile industry can be devised in two areas. The first
one corresponds to hours around the midday when the CPV/T system work autonomously and
guarantee the dyeing temperature 200°C, and the second one corresponds to a combined system
(CPV/T +boiler) to reach the required temperature. Even though, during the boiler operating
hours the amount of consumed gas and electricity will be reduced due the high outlet
temperature insured by the CPV/T system. This will enhance the global system efficiency.
Fig.10.Hourly load for heating water of the dyeing task in the studied textile industry.
Otherwise, Fig. 11 shows a comparison between the analyzed operational costs of the
cogeneration system and the conventional one (boiler). The analyzed operational costs include
the prices of the consumed gas and electricity during the whole life span of the installation. One
can observe that the analyzed operational costs of the conventional system are about two times
those of the proposed system, using a CPV/T back-up system since the first operational years.
Besides, due to the considered linear gas and electricity inflation prices the same conclusion
can be deduced during the whole system life span. Even though, we did not consider the
decreasing prices of the CPV/T technology (particularly the high-concentration PV cells), these
outcomes prove the economic-viability of the cogeneration CPV/T system.
4 8 12 16 20
0
50
100
150
200
250
autonomous CPV/T system
combined system (CPV/T + boiler)
autonomous CPV/T system
required temperature
of dyeing task (200°C)
combined system
(CPV/T +boiler)
outlet
tem
pera
ture
(°C
)
time (h)
Fig.11. Comparative between the analyzed operational costs of the cogeneration system (CPV/T-boiler)
and the conventional existing system (boiler).
5. Conclusions
In this paper, the potential of the concentrating photovoltaic technology has been evaluated
under the conditions of Monastir city, Tunisia. This issue was based on the simulation of a
(CPV/T) system under distinctive operating conditions, dedicated to a textile industry
application.
The effect of several parameters has been investigated in order to optimize the performance
of the proposed cogeneration plant. It has been concluded that the increase of the solar radiation
leads to an increase of thermal and electrical efficiencies. Besides, low flow rates provide the
best compatibility between electrical and thermal efficiencies because higher flow rates depress
heat transfer between the fluid and the absorber receiver and therefore the useful energy
absorbed will decrease and will influence the electrical power which reaches low values. Also,
the increase of the useful absorbed heat power leads to a higher electrical efficiencies.
Moreover, it was found that the produced power of the CPV/T system is inversely
proportional to the heat loss coefficient. Hence, it is fundamental to reduce loss damage to
achieve optimum performances. The optimized CPV/T system with storage meeting the dyeing
task loads is composed of three modules covering (40*3 m2) and an outlet flow of hot water
equal to 660 Kg/h. This proposed solution can supply autonomously an outlet hot water
temperature reaching a maximum value of 220°C at midday and attain values about 200 °C
surrounding this time lapse at least 5 hours per day. Hence, the diurnal cumulated electrical
energy can reach the value of 56 kWh with an average power of 3 kW while the thermal energy
capacity is about 198 kWh with an average power rating 11 kW. Assuming a CPV/T lifetime
equal to 20 years, respect of an initial investment of approximately 34 k€, a NPV about 33 k€
and an internal rate of return equal to 19% have been found. This presents a promising outcome,
and especially with the actual unremitting rise of electricity and gas prices and the decline in
CPV/T technology cost.
References
El Ouderni, A.R., Taher, M., Souheil, El.A., Sassi, B.N., 2013. Experimental assessment
of the solar energy potential in the gulf of Tunis, Tunisia. Renewable and Sustainable
Energy Reviews 20, 155–168.
Chow, T.T., 2010.A review on photovoltaic/thermal hybrid solar technology. Applied
Energy 87, 365–379.
Xu, X., Meyers, M.M., Sammakia, B.G., Murray, B.T., Chen, C., 2013. Performance and
reliability analysis of hybrid concentrating photovoltaic/thermal collectors with tree-
shaped channel nets’ cooling system. IEEE Trans. Compon. Packag. Manuf. Technol.
6, 967–977.
Whitfield, G.R., Bentley, R.W., Weatherby, C.K., Hunt, A.C., Mohring, H.D., Klotz, F.H.,
Keuber, P., Minano, J.C., Alarte-Garvy, E., 2000. The development and testing of
small concentrating PV system. Solar Energy 67, 23–34
Cappelletti, A., Reatti, Martelli, F., 2015. Numerical and Experimental Analysis of a CPV/T
Receiver Suitable for Low Solar Concentration Factors. Energy Procedia 82, 724–729.
Zondag, H.A., Vries, D.W., Van Helden,W.G.J., Van Zolingen, R. J. C., Van Steenhoven,
A.A., 2002. The thermal and electrical yield of a PV-thermal collector. Solar Energy
72, 113–128.
Reatti, M. K., Kazimierczuk, M., Catelani, L., Ciani, 2015. Linear solar PV/T concentrator
monitoring system and derivation of performance index", Proc. IEEE Int. Instrum.
Meas. Technol. Conf. (I2MTC), pp. 1285–1290.
Buonomano, A., Calise, F., Dentice, M., Vanoli, L., 2013. A novel solar trigeneration
system based on concentrating photovoltaic/thermal collectors. Part 1: Design and
simulation model. Energy 61, 59–71.
Davide, D.C., Bortolato, M., Padovan, A., Quaggia, M., 2014. Experimental and numerical
study of a parabolic trough linear CPVT system. Energy Procedia 57, 255–264.
Bosco, N., Sweet, C., Ludowise, M., Kurtz, S., 2012. An Infant mortality study of III–V
multijunction concentrator cells. IEEE Photovoltaic; 2:411–6.Available from <http://
dx.doi.org/10.1109/Jphotov.2012.2199082>.
Zondag, H A., 2008. Flat-plate PV thermal collectors and systems: a review. Renewable
and Sustainable Energy Reviews 12, 891–896.
Skoplaki, E., Palyvos, J A., 2009. On the temperature dependence of photovoltaic module
electrical performance: a review of efficiency/power correlations. Solar Energy 83,
614–638.
Calise, F., Palombo, A., Vanoli, L., 2012 .A finite-volume model of a parabolic trough
photovoltaic/thermal collector: Energetic and exergetic analyses Francesco. Energy
46, 283–294.
Xu, Ji., Ming, Li., Weidong, Lin., Wenbo, Wang., Liuling, Wang., Xi Luo., 2012. Modeling
and Characteristic Parameters Analysis of a Trough Concentrating
Photovoltaic/Thermal System with GaAs and Super Cell Arrays. International Journal
of Photo energy Volume, ID–782560.
Coventry Joe, S., 2005. Performance of a concentrating photovoltaic/thermal solar
collector. Solar Energy 78, 211–222.
Gibart, Buffet, 2008.Etude d’un capteur solaire mixste-photovoltaique thermique à
concentration, Convention : No. 459–78-1 ESF.
Quaia, V., Lughi, M., Giacalone,G., Vinzi , 2012. Technical-economic evaluation of a
Combined Heat and Power Solar (CHAPS) generator based on concentrated
photovoltaics’. International Symposium on Power Electronics, Electrical Drives,
Automation and Motion, IEEE.
Ming, Li., Xu, Ji., Guoliang, Li., Shengxian, Wei., YingFeng, Li., Feng, Shi., 2011.
Performance study of solar cell arrays based on a Trough Concentrating
Photovoltaic/Thermal system, Applied Energy 88, 3218–3227.
Rosell, J.I., Vallverdú, X., Lechón, M.A., Ibáñez M., 2005. Design and simulation of a low
concentrating photovoltaic/thermal system. Energy Conversion and Management 46,
3034–3046.
Sharan, S.N., Mathur, S.S., Kandpal, T.C., 1987. Analytical performances evaluation of
combined photovoltaic-thermal concentrator-receiver systems with linear absorbers.
Energy Conversion and management 27,361–365.
Xu, G., Xiaosong, Zh., Shiming D., 2011. Experimental study on the operating
characteristics of a novel low-concentrating solar photovoltaic/thermal integrated heat
pump water heating system. Applied Thermal Engineering 31, 3689–3695.
Al-Alili, A., Hwang, Y., Radermacher, R., Kubo, I., 2012. A high efficiency solar air
conditioner using concentrating photovoltaic/thermal collectors. Applied Energy
93,138–147.
Chemisana, D., Ibáñez, M., Rosell, J.I., 2011.Characterization of a photovoltaic-thermal
module for Fresnel linear concentrator. Energy Conversion and Management 52,
3234–3240.
Mittelman, G., Kribus, A., Dayan, A., 2007. Solar cooling with concentrating
photovoltaic/thermal (CPVT) systems. Energy Conversion and Management 48,
2481–2490.
Calise, F., Vanoli, L., 2012. Parabolic Trough Photovoltaic/Thermal Collectors: Design
and Simulation Model. Energies 5, 4186–4208.
Mittelman G., Abraham K., Ornit M., Dayan, A., 2007. Water desalination with
concentrating photovoltaic/thermal (CPVT) systems. Solar Energy 83, 1322–1334.
Nishioka, K., Takamoto, T., Agui, T., Kaneiwa, M., Uraoka, Y., Fuyuki, T, 2006. Annual
output estimation of concentrator photovoltaic systems using high-efficiency
InGaP/InGaAs/Ge triple-junction solar cells based on experimental solar cell’s
characteristics and field-test meteorological data. Sol. Energy Mater. Sol. Cells 90,
57–67.
Jiang, S., Peng, Hu., Songping, M., Chen, Z., 2010. Optical modeling for a two-stage
parabolic trough concentrating photovoltaic/thermal system using spectral beam
splitting technology. Solar Energy Materials & Solar Cells 94, 1686–1696.
Otanicar, T P., Theisen, S., Norman T., Tyagi, H., Robert, A., Taylor, c., 2015. Envisioning
advanced solar electricity generation: Parametric studies of CPV/T systems with
spectral filtering and high temperature PV. Applied Energy 140, 224–233.
Kribus, A., Daniel, K., Mittelman, G., Hirshfeld, A., Flitsanov, Y., Dayan, A., 2006. A
miniature concentrating photovoltaic and thermal system. Energy Conversion and
Management 47, 3582–3591.
Vorobiev, Y., González-Hernández, J., Vorobiev, P., Bulat, L., 2006. Thermal photovoltaic
solar hybrid system for efficient solar energy conversion. Solar Energy 80, 170-176.
Kosmadakis, G., Manolakos, D., Papadakis, G., 2011. Simulation and economic analysis of
a CPV/thermal system coupled with an organic Rankine cycle for increased power
generation. Solar Energy 85, 308–24.
Klein, S.A., Beckman, W., Mitchell, JW., Duffie, J., Duffie, NA., Freeman, TL., 2006.
TRNSYS: A Transient System Simulation Program, Solar Energy Laboratory,
University of Wisconsin Madison USA. Available from
<http://sel.me.wisc.edu/trnsys>.
John, A., Duffie, J., William, A., Beckman. Solar Engineering of Thermal Processes. GEAR
TEAM mechanical engineers.
Davide, D C., Matteo, B., Andrea, P., Michele, Q., 2014. Experimental and numerical study
of a parabolic trough linear CPVT system. Energy Procedia 57, 255–264.
Sherif, R.R., King, H.L., Cotal, D.C., Law, C.M., Fetzer, K., Edmondson, G.S. Glenn,G.
Kinsey, D. Krut, N.H. Karam, 2006. Concentrator triple-junction solar cells and
receivers in point focus and dense array modules. In European PV Conference,
Dresden.
Carlo, R., Fabio, P., 2013. Design And modeling of a concentrating photovoltaic thermal
(HCPVT) system for a domestic application. Energy and Buildings 62, 392–402